Owls’ wings could hold key to silent wind turbines

Editor’s note: This article was published in ScienceDaily, with materials provided by provided by IOP Publishing. A new study has revealed how inspiration from owls’ wings could allow aircraft and wind turbines to become even quieter.

Inspiration from owls could lead to a new noise-suppression mechanism for wind turbines (and other machines such as multi-rotor drones), thanks to new research based on owl-inspired feather wing models.

Researchers from Japan and China studied the serrations in the leading edge of owls’ wings, gaining new insight into how they work to make the birds’ flight silent.

Their results, published in the journal Bioinspiration and Biomimetics, point towards potential mechanisms for noise suppression in wind turbines, aircraft, multi-rotor drones, and other machines.

Lead author Professor Hao Liu, from Chiba University, Japan, said: “Owls are known for silent flight, owing to their unique wing features, which are normally characterised by leading-edge serrations, trailing-edge fringes and velvet-like surfaces.

“We wanted to understand how these features affect aerodynamic force production and noise reduction, and whether they could be applied elsewhere.”

The researchers analysed owl-inspired feather wing models with and without leading edge serrations, by combining large-eddy simulations — a mathematical model for turbulence used in computational fluid dynamics to simulate air flows — and Particle-Image Velocimetry (PIV) and force measurements in a low-speed wind tunnel.

They discovered leading-edge serrations can passively control the transition between laminar, or streamline air flow, and turbulent air flow over the upper wing surface, at angles of attack (AoA) between 0° and 20° . This means they play a crucial role in aerodynamic force and sound production.

Professor Liu said: “We found, however, that a trade-off exists between force production and sound suppression. Serrated leading-edges reduce aerodynamic performance at lower AoAs than 15° compared to clean leading-edges, but can achieve noise reduction and aerodynamic performance at AoAs above 15°, which owl wings often reach in flight.

“These owl-inspired leading edge serrations, if applied to wind turbine blades, aircraft wings or drone rotors, could provide a useful biomimetic design for flow control and noise reduction.

“At a time when issues of noise are one of the main barriers to the building of wind turbines, for example, a method for reducing the noise they generate is most welcome.”